Add masked LSTM support

Signed-off-by: Yu Cong <congyc@amazon.com>

tests/test_lstm.py

@@ -793,5 +793,212 @@ def func(x):
             return tf.identity(y[0], name="output")
         self.run_test_case(func, {"input:0": x_val}, [], ["output:0"], rtol=1e-05, atol=1e-06)
 
+    @check_tf_min_version("2.0")
+    @skip_tf_versions("2.1", "Bug in TF 2.1")
+    def test_keras_masked_lstm_embedding_unidirectional(self):
+        for go_backwards in [True, False]:
+            for return_sequences in [True, False]:
+                timesteps = 4
+                # Note: masked LSTM only support post-padded input after conversion
+                # test case sequence_lens = [4, 2, 0]
+                x_val = np.array([
+                    [1, 2, 3, 4],
+                    [5, 6, 0, 0],
+                    [0, 0, 0, 0]
+                ], dtype=np.int32)
+
+                model_in = tf.keras.layers.Input((timesteps,), dtype="int32")
+                x_embedding = tf.keras.layers.Embedding(
+                    input_dim=10,
+                    output_dim=5,
+                    mask_zero=True,
+                    embeddings_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=41),
+                )(model_in)
+
+                # RNN layer inherits the mask propagated from above embedding layer
+                model_out = tf.keras.layers.LSTM(
+                    units=5,
+                    go_backwards=go_backwards,
+                    return_sequences=return_sequences,
+                    return_state=True,
+                    kernel_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=42),
+                    bias_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=43),
+                    recurrent_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=44),
+                )(x_embedding)
+                model = tf.keras.models.Model(inputs=model_in, outputs=model_out)
+
+                def func(x):
+                    y = model(x)
+                    if return_sequences:
+                        return (
+                            # skipping output Y when return_sequences=True due to inconsistent
+                            # ORT and TF behaviors: https://sim.amazon.com/issues/NEMORT-1712
+                            tf.identity(y[1], name="output_yh"),
+                            tf.identity(y[2], name="output_yc"))
+                    return(
+                        tf.identity(y[0], name="output_y"),
+                        tf.identity(y[1], name="output_yh"),
+                        tf.identity(y[2], name="output_yc"))
+
+                output_list = ["output_yh:0", "output_yc:0"] if return_sequences \
+                    else ["output_y:0", "output_yh:0", "output_yc:0"]
+                self.run_test_case(func, {"input:0": x_val}, [], output_list, rtol=1e-05, atol=1e-06)
+
+    @check_tf_min_version("2.0")
+    @skip_tf_versions("2.1", "Bug in TF 2.1")
+    def test_keras_masked_lstm_embedding_bidirectional(self):
+        for return_sequences in [False, True]:
+            timesteps = 4
+            # Note: masked LSTM only support post-padded input after conversion
+            # test case sequence_lens = [4, 2, 0]
+            x_val = np.array([
+                [1, 2, 3, 4],
+                [5, 6, 0, 0],
+                [0, 0, 0, 0]
+            ], dtype=np.int32)
+
+            model_in = tf.keras.layers.Input((timesteps,), dtype="int32")
+            x_embedding = tf.keras.layers.Embedding(
+                input_dim=10,
+                output_dim=5,
+                mask_zero=True,
+                embeddings_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=41),
+            )(model_in)
+
+            # RNN layer inherits the mask propagated from above embedding layer
+            lstm_layer = tf.keras.layers.LSTM(
+                units=5,
+                go_backwards=False,
+                return_sequences=return_sequences,
+                return_state=True,
+                kernel_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=42),
+                bias_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=43),
+                recurrent_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=44),
+            )
+            model_out = tf.keras.layers.Bidirectional(lstm_layer)(x_embedding)
+            model = tf.keras.models.Model(inputs=model_in, outputs=model_out)
+
+            def func(x):
+                y = model(x)
+                if return_sequences:
+                    return (
+                        # skipping output Y when return_sequences=True due to inconsistent
+                        # ORT and TF behaviors: https://sim.amazon.com/issues/NEMORT-1712
+                        tf.identity(y[1], name="output_yh_f"),
+                        tf.identity(y[2], name="output_yc_f"),
+                        tf.identity(y[3], name="output_yh_r"),
+                        tf.identity(y[4], name="output_yc_r"))
+                return(
+                    tf.identity(y[0], name="output_y_concat"),
+                    tf.identity(y[1], name="output_yh_f"),
+                    tf.identity(y[2], name="output_yc_f"),
+                    tf.identity(y[3], name="output_yh_r"),
+                    tf.identity(y[4], name="output_yc_r"))
+
+            output_list = ["output_yh_f:0", "output_yc_f:0", "output_yh_r:0", "output_yc_r:0"] if return_sequences \
+                else ["output_y_concat:0", "output_yh_f:0", "output_yc_f:0", "output_yh_r:0", "output_yc_r:0"]
+
+            # translate single BiLSTM to two forward LSTMs
+            self.run_test_case(func, {"input:0": x_val}, [], output_list, rtol=1e-05, atol=1e-06,
+                               require_lstm_count=2)
+
+    @check_tf_min_version("2.0")
+    @skip_tf_versions("2.1", "Bug in TF 2.1")
+    def test_keras_masked_lstm_unidirectional(self):
+        for go_backwards in [True, False]:
+            for return_sequences in [True, False]:
+                batch_size, timesteps, feat = 3, 4, 5
+                in_shape = (timesteps, feat)
+                x_val = np.random.uniform(size=[batch_size, timesteps, feat]).astype(np.float32)
+                # Note: masked LSTM only support post-padded input after conversion
+                # test case sequence_lens = [4, 2, 0]
+                x_val[1, 2:, :] = 0.
+                x_val[2, :, :] = 0.
+
+                model_in = tf.keras.layers.Input(shape=in_shape, dtype="float32")
+                x_masked = tf.keras.layers.Masking(mask_value=0.)(model_in)
+
+                # RNN layer inherits the mask propagated from above mask layer
+                model_out = tf.keras.layers.LSTM(
+                    units=5,
+                    go_backwards=go_backwards,
+                    return_sequences=return_sequences,
+                    return_state=True,
+                    kernel_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=42),
+                    bias_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=43),
+                    recurrent_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=44),
+                )(x_masked)
+                model = tf.keras.models.Model(inputs=model_in, outputs=model_out)
+
+                def func(x):
+                    y = model(x)
+                    if return_sequences:
+                        return (
+                            # skipping output Y when return_sequences=True due to inconsistent
+                            # ORT and TF behaviors: https://sim.amazon.com/issues/NEMORT-1712
+                            tf.identity(y[1], name="output_yh"),
+                            tf.identity(y[2], name="output_yc"))
+                    return(
+                        tf.identity(y[0], name="output_y"),
+                        tf.identity(y[1], name="output_yh"),
+                        tf.identity(y[2], name="output_yc"))
+
+                output_list = ["output_yh:0", "output_yc:0"] if return_sequences \
+                    else ["output_y:0", "output_yh:0", "output_yc:0"]
+                self.run_test_case(func, {"input:0": x_val}, [], output_list, rtol=1e-05, atol=1e-06)
+
+    @check_tf_min_version("2.0")
+    @skip_tf_versions("2.1", "Bug in TF 2.1")
+    def test_keras_masked_lstm_bidirectional(self):
+        for return_sequences in [False, True]:
+            batch_size, timesteps, feat = 3, 4, 5
+            in_shape = (timesteps, feat)
+            x_val = np.random.uniform(size=[batch_size, timesteps, feat]).astype(np.float32)
+            # Note: masked LSTM only support post-padded input after conversion
+            # test case sequence_lens = [4, 2, 0]
+            x_val[1, 2:, :] = 0.
+            x_val[2, :, :] = 0.
+
+            model_in = tf.keras.layers.Input(shape=in_shape, dtype="float32")
+            x_masked = tf.keras.layers.Masking(mask_value=0.)(model_in)
+
+            # RNN layer inherits the mask propagated from above mask layer
+            lstm_layer = tf.keras.layers.LSTM(
+                units=5,
+                go_backwards=False,
+                return_sequences=return_sequences,
+                return_state=True,
+                kernel_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=42),
+                bias_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=43),
+                recurrent_initializer=tf.random_uniform_initializer(0.0, 1.0, seed=44),
+            )
+            model_out = tf.keras.layers.Bidirectional(lstm_layer)(x_masked)
+            model = tf.keras.models.Model(inputs=model_in, outputs=model_out)
+
+            def func(x):
+                y = model(x)
+                if return_sequences:
+                    return (
+                        # skipping output Y when return_sequences=True due to inconsistent
+                        # ORT and TF behaviors: https://sim.amazon.com/issues/NEMORT-1712
+                        tf.identity(y[1], name="output_yh_f"),
+                        tf.identity(y[2], name="output_yc_f"),
+                        tf.identity(y[3], name="output_yh_r"),
+                        tf.identity(y[4], name="output_yc_r"))
+                return(
+                    tf.identity(y[0], name="output_y_concat"),
+                    tf.identity(y[1], name="output_yh_f"),
+                    tf.identity(y[2], name="output_yc_f"),
+                    tf.identity(y[3], name="output_yh_r"),
+                    tf.identity(y[4], name="output_yc_r"))
+
+            output_list = ["output_yh_f:0", "output_yc_f:0", "output_yh_r:0", "output_yc_r:0"] if return_sequences \
+                else ["output_y_concat:0", "output_yh_f:0", "output_yc_f:0", "output_yh_r:0", "output_yc_r:0"]
+
+            # translate single BiLSTM to two forward LSTMs
+            self.run_test_case(func, {"input:0": x_val}, [], output_list, rtol=1e-05, atol=1e-06,
+                               require_lstm_count=2)
+
+
 if __name__ == '__main__':
     unittest_main()

tf2onnx/onnx_opset/tensor.py

@@ -2260,15 +2260,25 @@ def version_10(cls, ctx, node, **kwargs):
                 const_axis_name = utils.make_name(f'const_{axis}')
                 const_axis = ctx.make_const(name=const_axis_name, np_val=np.array([axis], dtype=np.int64))
 
-                # Add a Constant node (seq_len) for ReverseSequence.
-                # Index 1 for the shape should not return 0, since rank(input) >=2
-                input_shape = ctx.make_node("Shape", [inputs[-1]], op_name_scope=rv2_node_name)
-                batch_size = ctx.make_node("Gather", [input_shape.output[0], const_one.output[0]],
-                                           op_name_scope=rv2_node_name)
-                axis_dim = ctx.make_node("Gather", [input_shape_node.output[0], const_axis.output[0]],
-                                         op_name_scope=rv2_node_name)
-                seq_array = ctx.make_node("Expand", [axis_dim.output[0], batch_size.output[0]])
-                inputs.append(seq_array.output[0])
+                # Add sequence_lens as ReverseSequence input
+                has_sequence_lens = node.get_attr_value("has_sequence_lens", False)
+                if not has_sequence_lens:
+                    # open-source impl: fill in dummy sequence_lens based on input shape
+                    # Add a Constant node (seq_len) for ReverseSequence.
+                    # Index 1 for the shape should not return 0, since rank(input) >=2
+                    input_shape = ctx.make_node("Shape", [inputs[-1]], op_name_scope=rv2_node_name)
+                    batch_size = ctx.make_node("Gather", [input_shape.output[0], const_one.output[0]],
+                                               op_name_scope=rv2_node_name)
+                    axis_dim = ctx.make_node("Gather", [input_shape_node.output[0], const_axis.output[0]],
+                                             op_name_scope=rv2_node_name)
+                    seq_array = ctx.make_node("Expand", [axis_dim.output[0], batch_size.output[0]])
+                    inputs.append(seq_array.output[0])
+                else:
+                    # masked backward LSTM:
+                    # sequence_lens is appended to ReverseV2's input by lstm_tf2_rewriter
+                    # to keep tensor post-padded after reverse
+                    seq_lens_casted = ctx.make_node("Cast", [node.input[-1]], attr={'to': TensorProto.INT64}).output[0]
+                    inputs.append(seq_lens_casted)
 
                 # Add a ReverseSequence node.